Techniques to perform forward error correction for an electrical backplane

ABSTRACT

Techniques to perform forward error correction for an electrical backplane are described.

RELATED APPLICATIONS

This application is a continuation of U.S. application Ser. No.13/348,341, filed Jan. 11, 2012, which is a continuation of U.S.application Ser. No. 12/964,271, filed Dec. 9, 2010, which is acontinuation of U.S. application Ser. No. 12/639,797, filed Dec. 16,2009, which is a continuation of U.S. application Ser. No. 11/325,765,filed Jan. 4, 2006. The entire teaching of the above applications isincorporated herein by reference.

BACKGROUND

High speed communication systems capable of higher throughput data ratesare emerging. For example, Gigabit Ethernet networks may communicateinformation at 10 gigabits-per-second (Gbps) or higher. High speedchannels typically realize a corresponding increase in error rates.Techniques such as forward error correction may be used to decrease theerror rates. Such techniques, however, may require a communicationsystem to communicate additional overhead in the form of errorcorrecting information. The additional overhead may decrease theeffective throughput for a communication system.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates one embodiment of a network interface.

FIG. 2 illustrates one embodiment of a physical layer unit.

FIG. 3 illustrates one embodiment of a forward error correcting block.

FIG. 4 illustrates one embodiment of an encoded data frame.

FIG. 5 illustrates one embodiment of a forward error correcting encoder.

FIG. 6 illustrates one embodiment of a pseudo-noise generator.

FIG. 7 illustrates one embodiment of a forward error correcting decoder.

FIG. 8 illustrates one embodiment of a decoded data frames.

FIG. 9 illustrates one embodiment of a first logic flow.

FIG. 10 illustrates one embodiment of a second logic flow.

FIG. 11 illustrates one embodiment of a third logic flow.

FIG. 12 illustrates one embodiment of a communications system.

FIG. 13 illustrates one embodiment of a first graph.

FIG. 14 illustrates one embodiment of a second graph.

FIG. 15 illustrates one embodiment of a third graph.

FIG. 16 illustrates one embodiment of a fourth graph.

FIG. 17 illustrates one embodiment of a fifth graph.

FIG. 18 illustrates one embodiment of a sixth graph.

FIG. 19 illustrates one embodiment of a seventh graph.

DETAILED DESCRIPTION

Various embodiments may be generally directed to forward errorcorrection (FEC) techniques. In particular, various embodiments may bedirected to FEC techniques for Ethernet operation over electricalbackplanes, also referred to as “Backplane Ethernet.” In one embodiment,for example, an apparatus may comprise a physical layer unit having aforward error correction sublayer to perform FEC using a single bit torepresent a two bit synchronization header. Error detection and/orcorrection information may replace the additional bit previously usedfor the two bit synchronization header. Stated differently, the FECsublayer compresses the two bit synchronization header to a single bit,and uses one of the synchronization bits of the two bit synchronizationheader to send error detection or correction information. In thismanner, the physical layer unit may use FEC techniques to decrease biterror rates (BER) without necessarily increasing communication overhead.Other embodiments are described and claimed.

FIG. 1 illustrates one embodiment of a network interface. FIG. 1illustrates a network interface 100. Network interface 100 may allow adevice to communicate information over a network. In variousembodiments, network interface 100 may represent any network interfacesuitable for use with a number of different Ethernet techniques asdefined by the Institute of Electrical and Electronics Engineers (IEEE)802.3 series of standards. For example, network interface 100 maycomprise a structure arranged to operate in accordance with the IEEE802.3-2005 standard. The IEEE 802.3-2005 standard defines 1000 megabitsper second (Mbps) operations (1000BASE-T) using four pair twisted copperCategory 5 wire, 10 Gbps operations using fiber cable, and 10 Gbpsoperations (10 GBASE-CX4) using copper twinaxial cable (collectivelyreferred to herein as “Gigabit Ethernet”). More particularly, networkinterface 100 may have a structure arranged to operate in accordancewith the IEEE Standard 802.3-2005 titled “IEEE Standard For InformationTechnology—Telecommunications and information exchange betweensystems—Local and metropolitan networks—Specific requirements Part 3:Carrier Sense Multiple Access with Collision Detection (CSMA/CD) AccessMethod and Physical Layer Specifications, Amendment: Ethernet Operationover Electrical Backplanes,” Draft Amendment P802.3ap/Draft 2.1, 2005(“Backplane Ethernet Specification”). Network interface 100, however, isnot necessarily limited to the techniques defined by these standards,and network interface 100 may use other techniques and standards asdesired for a given implementation. The embodiments are not limited inthis context.

As shown in FIG. 1, network interface 100 may include a media accesscontrol (MAC) unit 105 and a physical (PHY) unit 110. In variousembodiments, MAC unit 105 and/or PHY unit 110 may be arranged to operatein accordance with one of the Ethernet architectures as previouslydescribed, such as the IEEE 802.3-2005 series of standards including theBackplane Ethernet Specification. Although FIG. 1 illustrates networkinterface 100 with a limited number of elements, it may be appreciatedthat network interface 100 may include more or less elements indifferent topologies and still fall within the scope of the embodiments.The embodiments are not limited in this context.

In one embodiment, for example, MAC unit 105 and/or PHY unit 110 may bearranged to operate in accordance with the Backplane EthernetSpecification. Backplane Ethernet combines the IEEE 802.3 MAC and MACControl sublayers with a family of Physical Layers defined to supportoperation over a modular chassis backplane. Backplane Ethernet supportsthe IEEE 802.3 MAC operating at 1000 Mbps and/or 10 Gbps. For 1000 Mbpsoperation, the family of 1000BASE-X PHY signaling systems is extended toinclude 1000BASE-KX. For 10 Gbps operation, two PHY signaling systemsare defined. For operation over four logical lanes, the 10 GBASE-Xfamily is extended to include 10GBASE-KX4. For serial operation, the10GBASE-R family is extended to include 10GBASE-KR (e.g., using variousserializer/deserializer or “SERDES” techniques). Backplane Ethernet alsospecifies an Auto-Negotiation function to enable two devices that sharea backplane link segment to automatically select the best mode ofoperation common to both devices.

With reference to the seven-layer Open System Interconnect (“OSI”)Reference Model developed by the International Standards Organization(“ISO”), MAC unit 105 implements MAC layer operations. The MAC layer isa sublayer of the data link layer. The data link layer is primarilyconcerned with transforming a raw transmission facility into acommunication line free of undetected transmission errors for use by thenetwork layer. The data link layer accomplishes this task by breakinginput data into data frames, transmitting the data frames sequentially,and processing acknowledgement frames. The MAC sublayer providesadditional functionality concerned with controlling access to broadcastnetworks (e.g., Ethernet). In the case of Ethernet architecture, forexample, the MAC sublayer may implement a CSMA/CD protocol.

In various embodiments, MAC unit 105 is coupled to PHY unit 110 via abi-directional link 115 to provide a data path between MAC unit 105 andPHY unit 110. Bi-directional link 115 is often referred to as a MediaIndependent Interface (“MII”), an xMII in the case of implementations of100 Mbps or higher, X attachment unit interface (“XAUI”) in the case of10 Gbps implementations, or X fiber interface (“XFI”) in the case ofdual path 10 Gbps implementations. In one embodiment, for example,bi-directional link 115 may comprise a 10 Gbps MII (XGMII) when MAC unit105 and/or PHY unit 110 are implemented for serial operations inaccordance with 10 GBASE-KR as defined by the Backplane EthernetSpecification. Bi-directional link 115 may use a 4-octet wide data path,for example, when implemented as an XGMII bi-directional link. In oneembodiment, for example, bi-directional link 115 may comprise a XAUIlink where the XGMII from MAC unit 105 is extended through a XGXSsublayer (e.g., XGMII extender sublayer) which provides XGMII on bothsides with XAUI used therebetween to extend it. The embodiments are notlimited in this context.

In various embodiments, PHY unit 110 implements physical layeroperations. The physical layer is primarily concerned with transmittingraw bits over physical medium 120, which may be some form of network.PHY unit 110 is coupled to physical medium 120 via a media dependentinterface (MDI) 125. Physical medium 120 may include variouscommunications media, such as an optical fiber, a twisted pairconductor, or the like. In one embodiment, for example, physical medium120 is a four pair twisted conductor, such as copper, conforming to aCategory 5, 6, 7 or the like cable. In the four pair twisted conductorembodiment, PHY unit 110 converts digital data received from MAC unit105 (e.g., 1000BASE-X or 10 GBASE-X) into analog symbols (e.g.,1000BASE-T or 10 GBASE-T) for transmission over physical medium 120. Forexample, PHY unit 110 may encode the digital data using Manchesterencoding or the like. Physical medium 120 may operate at any number ofbandwidths, including 100 Mbps, 1 Gbps, 10 Gbps, and so forth. PHY unit110 may be connected or coupled to physical medium 120 using anyconnectors suitable for a given type of communications media, such as anelectrical connector, optical connector, and so forth. In oneembodiment, for example, PHY unit 110 may be connected or coupled tophysical medium 120 to support operation over differential, controlledimpedance traces on a printed circuit board with two or more connectorsand total length up to at least 1 m in accordance with the BackplaneEthernet Specification. The embodiments are not limited in this context.

In various embodiments, PHY unit 110 may further implement operationsfor various sublayers of the physical layer, including a physical codingsublayer (“PCS”), a physical medium attachment (“PMA”) sublayer, and aphysical medium dependent (“PMD”) sublayer. In one embodiment, forexample, PHY unit 110 may implement FEC operations for the varioussublayers, such as used between the PMA sublayer and PCS sublayer, forexample. PHY unit 110 and its corresponding FEC operations may bedescribed in more detail with reference to FIG. 2.

FIG. 2 illustrates one embodiment of a physical layer unit. FIG. 2illustrates a block diagram for PHY unit 110. In one embodiment, forexample, PHY unit 110 may be arranged to operate in accordance with any10 GBASE-R signaling system to reduce error rate, such as a 10 GBASE-KRPHY, for example. Backplane Ethernet extends the family of 10 GBASE-RPhysical Layer signaling systems to include 10 GBASE-KR. The 10 GBASE-KRPHY specifies 10 Gbps operation over two differential controlledimpedance pairs of traces, with one pair for transmit and one pair forreceive. Although some embodiments may be described using a 10 GBASE-KRsignaling system by way of example, any 10 GBASE-R signal system may beused and still fall within the scope of the embodiments. The embodimentsare not limited in this context.

In various embodiments, PHY unit 110 may include a PCS sublayer 210, aFEC sublayer 230, and a PMA sublayer 240. PCS sublayer 210 and PMAsublayer 240 may implement PCS and PMA operations, respectively, for anyembodiment that uses 10 GBASE-R signaling systems to reduce error rate,such as a 10 GBASE-KR PHY, for example. PCS sublayer 210 may beconnected to bi-directional link 115 and FEC sublayer 230. PCS sublayer210 may include a PCS transmitter 212, a PCS receiver 220, a blocksynchronizer 226, and a BER and synchronization header monitor (BSHM)228. PCS transmitter 212 may include a PCS encoder 214, a PCS scrambler216, and a gearbox 218. PCS receiver 220 may include a PCS decoder 222and a PCS descrambler 224.

In various embodiments, FEC sublayer 230 may implement FEC operationsfor any embodiment that uses 10 GBASE-R signaling systems to reduceerror rate, such as a 10 GBASE-KR PHY, for example. The FEC operationsmay provide a coding gain to increase the link budget and bit error rate(BER) performance on a broader set of back plane channels as defined inthe Backplane Ethernet Specification. The FEC operations may alsoprovide additional margin to account for variations in manufacturing andenvironmental conditions.

In various embodiments, FEC sublayer 230 may be implemented inaccordance with various design goals and performance constraints. Forexample, FEC sublayer 230 may support FEC operations for a 10 GBASE-KRPHY, full duplex mode operations for the Ethernet MAC (e.g., MAC unit105), operations for the physical layer sublayers defined for 10BASE-KID(e.g., PCS, PMA and PMD), a 10.3125 Gbps effective data rate at theservice interface presented by the PMA sublayer, operations over linksconsistent with differential controlled impedance traces on a printedcircuit board with two con 1 total length up to at least one metermeeting the requirements of the Backplane Ethernet Specification, and/orsupport a BER objective of 10⁻¹² or better. The embodiments are notnecessarily limited to these design goals and/or performanceconstraints.

In various embodiments, FEC sublayer 230 may include a FEC ServiceInterface. The FEC Service Interface allows the 10 GBASE-KR PCS sublayerto transfer information to and from FEC sublayer 230. The FEC servicesare defined in an abstract manner and do not imply any particularimplementation. The FEC Service Interface supports an exchange ofdata-units between PCS entities on either side of a 10 GBASE-KR linkusing request and indication primitives. FEC sublayer 230 maps thedata-units into FEC frames and passes the FEC frames to PMA sublayer240, and vice versa.

In various embodiments, the FEC Service Interface of FEC sublayer 230may include a FEC_UNITDATA.request (tx_data-group<15:0>) primitive. TheFEC_UNITDATA.request primitive defines the transfer of data in the formof constant-width data-units from PCS sublayer 210 to FEC sublayer 230.The data supplied via FEC_UNITDATA.request is mapped by the FEC transmitprocess into the payload capacity of the outgoing FEC frame stream. TheFEC_UNITDATA.request primitive includes a parameter oftx_data-group<15:0>. The data conveyed by FEC_UNITDATA.request is, forexample, a 16-bit vector representing a single data-unit that has beenprepared for transmission by the 10 GBASE-KR PCS transmit process. PCSsublayer 210 sends tx_data-group<15:0> to FEC sublayer 230 at a nominalrate of 644.53125 Megahertz (MHz), for example, which corresponds to the10 GBASE-KR signaling speed of 10.3125 GBd. Upon receipt of thisprimitive, the FEC transmit process of FEC sublayer 230 maps the dataconveyed by the tx_data unit<15:0> parameter into the payload of thetransmitted FEC frame block stream, adds FEC overhead as required,scrambles the data, and transfers the result to PMA sublayer 240 via thePMA_UNITDATA.request primitives.

In various embodiments, the FEC Service Interface of FEC sublayer 230may include a FEC_UNITDATA.indication (rx_data-group<15:0>) primitive.The FEC_UNITDATA.indication primitive defines the transfer of receiveddata in the form of constant-width data-units from FEC sublayer 230 toPCS sublayer 210. The FEC_UNITDATA.indication primitive is generated bythe FEC receive process in response to FEC block data received from PMAsublayer 240. The FEC_UNITDATA.indication primitive includes a parameterof rx_data-group<15:0>. The rx_data-group<15:0> parameter is, forexample, a 16-bit vector that represents the data-unit transferred byFEC sublayer 230 to PCS sublayer 210. FEC sublayer 230 sends onerx_data-group<15:0> to PCS sublayer 210 whenever it has delineatedapproximately 16 bits of valid payload information from the incoming FECdata stream received from PMA sublayer 240. The nominal rate ofgeneration of the FEC_UNITDATA.indication primitive is, for example,644.53125 Mtransfers/s.

In various embodiments, the FEC Service Interface of FEC sublayer 230may include a FEC_SIGNAL.indication (SIGNAL_OK) primitive. TheFEC_SIGNAL.indication primitive is sent by FEC sublayer 230 to PCSsublayer 210 to indicate the status of the FEC receive process. TheFEC_SIGNAL.indication primitive is generated by the FEC receive processin order to propagate the detection of severe error conditions, such asno valid signal being received from PMA sublayer 240, to PCS sublayer210. The FEC_SIGNAL.indication includes a parameter of SIGNAL_OK. TheSIGNAL_OK parameter can take one of two values: OK or FAIL. A value ofOK denotes that the FEC receive process is successfully delineatingvalid payload information from the incoming data stream received fromPMA sublayer 240, and this payload information is being presented to PCSsublayer 210 via the FEC_UNITDATA.indication primitive. A value of FAILdenotes that errors have been detected by the FEC receive process thatprevent valid data from being presented to PCS sublayer 210. In thiscase the FEC_UNITDATA.indication primitive and its associatedrx_data-group<15:0> parameter may be superfluous. FEC sublayer 230generates the FEC_SIGNAL.indication primitive to PCS sublayer 210whenever there is a change in the value of the SIGNAL_OK parameter.

In principle operation, FEC sublayer 230 performs FEC operations betweenPCS sublayer 210 and PMA sublayer 240. FEC sublayer 230 may include anFEC encoder 232 that receives data from PCS sublayer 210 viatx_data-group<15:0>. FEC encoder 232 transcodes 64b/66b words, performsFEC coding and framing, scrambles, and sends the FEC encoded data to PMAsublayer 240. FEC sublayer 230 may also include an FEC decoder and blocksynchronizer (FDBS) 234. FDBS 234 receives data from PMA sublayer 240via rx_data-group<15:0> and a PMA-SIGNAL.indicate primitive. FDBS 234performs descrambling, achieves FEC framing synchronization, decodes theFEC code, correcting data where necessary and possible, re-codes 64b/66bwords, and sends the data to PCS sublayer 210 via rx_data-group<15:0>and a FEC-SIGNAL.indicate primitive.

In various embodiments, FEC sublayer 230 may use an FEC code. In oneembodiment, for example, the FEC code may comprise a shortened cycliccode (2112, 2080) for error checking and forward error correction. TheFEC block length is 2112 bits. The FEC code encodes 2080 bits of payload(or information symbols) and adds 32 bits of overhead (or paritysymbols). The code is systematic, which means that the informationsymbols are not disturbed in anyway in the encoder and the paritysymbols are added separately to the end of each block. The (2112, 2080)code is constructed by shortening the cyclic code (42987, 42955). Thiscyclic code may correct an error burst of t=11 bits per block. It is asystematic code well suited for correction of the burst errors typicalin a backplane channel, such as resulting from error propagation in thereceive equalizer.

FIG. 3 illustrates one embodiment of an FEC block. FIG. 3 illustrates anFEC block 300. FEC block 300 may provide an example of a data formatsuitable for use by FEC sublayer 230. Although some embodiments maydescribe FEC block 300 in terms of a data block, it may be appreciatedthat FEC block 300 may also refer to any delineated data set, such as apacket, frame, unit, cell, segment, fragment, and so forth. Theembodiments are not limited in this context.

In one embodiment, for example, the total block length of FEC block 300is 2112 bits (e.g., [32×65]+32=2112 bits). Each FEC block 300 contains32 rows of words 0-31. Each word 0-31 comprises 65 bit, with 64 bits ofpayload carrying the information symbols from PCS sublayer 210, and 1bit of overhead (e.g., T bits T₀ to T₃₁). At the end of each FEC block300 there are 32 bits of overhead in the form of parity check bits.Transmission is from left to right within each row, and from top tobottom between rows. It may be appreciated that any number of words andparity check bits may be used for a given implementation, therebyleading to variations in a total size for FEC block 300. Furthermore, itmay be appreciated that the parity check bits may be added to FEC block300 anywhere within FEC block 300, including prepending the parity checkbits to FEC block 300 before the words, appending the parity check bitsto FEC block 300 after the words, interleaving the parity check bits toFEC block 300 between the various words, and so forth. The embodimentsare not limited in this context.

FIG. 4 illustrates one embodiment of an encoded data frame. FIG. 4illustrates a set of data frames 400. Data frames 400 may provideexamples of input and output frames used by FEC sublayer 230. FECsublayer 230 may receive PCS frame 402 from PCS sublayer 210. PCS frame402 may include multiple PCS blocks 404. For example, PCS blocks 404 maycomprise 64b/66b PCS blocks. FEC encoder 232 of FEC sublayer 230 mayencode PCS blocks 404, and place the encoded PCS blocks 404 into an FECframe 412. FEC encoder 232 does not decrease the symbol rate from PCSlayer 202, however, when performing FEC encoding operations. Rather, FECencoder 232 uses 32 compressed synchronization bits from the 64b/66bencoded data of PCS blocks 404 to form an FEC block (e.g., similar toFEC block 300) having 32 parity check bits.

In general operation, PCS sublayer 210 maps 64 bits of scrambled payloaddata and 2 bits of unscrambled synchronization header data into 66-bitencoded blocks (e.g., PCS blocks 404). The 2-bit synchronization headerdata forms synchronization header 406. Synchronization header 406 allowsestablishment of 64b/66b PCS block boundaries by the PCS synchronizationprocess. The two bits of synchronization header 406 may be set to “01”for data blocks and “10” for control blocks. Synchronization header 406is the only position in 64b/66b PCS blocks 404 that always contains atransition, and this feature of the code is used to establish 64b/66bblock boundaries.

In general operation, FEC encoder 232 of FEC sublayer 230 receives PCSframe 402 from PCS sublayer 210. FEC encoder 232 replaces the twosynchronization bits of synchronization header 406 with a single bit,referred to herein as a transcode bit. Stated differently, FEC encoder232 compresses the two synchronization bits of synchronization header406 into a single transcode bit. The transcode bit carries the state ofboth 10 GBASE-KR synchronization bits for the associated payload. Thismay be achieved by eliminating the first synchronization bit in PCSblock 404, and preserving only the second bit. The value of the secondbit uniquely defines the value of the removed first bit since it isalways an inversion of the first bit. The transcode bits are furtherscrambled as described later to ensure DC balance.

FEC encoder 232 takes 32 PCS blocks 404 and encodes it into a single FECblock of 2112 bits. FEC encoder 232 transcodes the 32 sequential 64b/66bPCS blocks 404 into 32 65-bit blocks, and computes 32 bits of FEC parityfor each of 32 PCS blocks 404 to generate a total of 32 parity checkbits. The 32 transcoded words and the 32 FEC parity bits may comprise anFEC block of 2112 bits (e.g., FEC block 300). After transcoding each of64b/66b to 65-bit blocks, FEC encoder 232 computes the FEC Parity on theentire 32 65-bit blocks. Taking 1 synchronization bit from each 66bblock creates 32-bit space at the end of 32 65-bit blocks. This 32-bitspace may be used to carry the 32-bit parity check. Parity is typicallycomputed on the entire FEC block, which in one embodiment is 2080 bits(e.g., 32×65 bits=2080 bits).

The error detection property of the FEC cyclic code is used to establishblock synchronization at FEC block boundaries at the receiver. Ifdecoding passes successfully, FDBS 234 produces 32 65-bit words, withthe first decoded bit of each word being the transcode bit. FDBS 234constructs the first synchronization bit of synchronization header 406by inverting the transcode bit. FDBS 234 sets a value for the secondsynchronization bit of synchronization header 406 to the value of thetranscode bit. FDBS 234 may send the reconstructed synchronizationheader 406 to PCS sublayer 210 for use by BSHM 228 and blocksynchronizer 226, for example.

FIG. 5 illustrates one embodiment of a forward error correcting encoder.FIG. 5 illustrates a block diagram for FEC encoder 232. As shown in FIG.5, FEC encoder 232 may comprise a reverse gearbox 502, a compressor 504,a selector 506, a parity generator 508, a pseudo-noise generator 510, amultiplexer 512, and a scrambler 514. Although FIG. 5 illustrates FECencoder 232 with a limited number of elements by way of example, it maybe appreciated that more or less elements may be used for FEC encoder232 as desired for a given implementation. The embodiments are notlimited in this context.

In operation, FEC encoder 232 sends transmit data-units to a PMA serviceinterface for PMA sublayer 240 via the PMA_UNITDATA.request primitive.When the transmit channel is in test-pattern mode, a test pattern ispacked into the transmit data-units that are sent to the PMA serviceinterface via the PMA_UNITDATA.request primitive.

In various embodiments, FEC encoder 232 may include a reverse gearbox502. Reverse gearbox 502 may connect, for example, to PCS gearbox 218 ofPCS sublayer 210 using the 16-bit tx_data-group<15:0>. Reverse gearbox502 adapts between the 66-bit width of the 64b/66b blocks and the 16-bitwidth of the PCS service interface for PCS sublayer 210. Reverse gearbox502 receives a 16-bit stream from the PCS service interface (e.g., PCSgearbox 218), and converts it back to 66-bit encoded blocks forprocessing by FEC encoder 232. Reverse gearbox 502 operates similar tothe block synchronization operations defined in the Backplane EthernetSpecification (e.g., 802.3-2005 specification, clause 49). When thetransmit channel is operating in normal mode, reverse gearbox 502receives data via the 16-bit FEC_UNITDATA.request primitive. Reversegearbox 502 will form a bit stream from the primitives by concatenatingrequests with the bits of each primitive in order to formtx_data-group<0> to tx_data-group<15>. Reverse gearbox 502 obtains alock on the 66-bit blocks in the bit stream using the synchronizationheaders, and outputs 66-bit blocks. Lock operations may be furtherdefined in the Backplane Ethernet Specification (e.g., 802.3-2005specification, clause 49). Reverse gearbox 502 may be needed only whenthe optional PMA compatibility interface named XSBI is implementedbetween PCS sublayer 210 and FEC sublayer 230, since the XSBI interfacepasses data via a 16-bit wide data path. When the XSBI interface is notimplemented, the internal width of the data path between PCS sublayer210 and FEC sublayer 240 may vary in accordance with a desiredimplementation. Accordingly, reverse gearbox 502 may be obviated forsome implementations depending on the width of the data path

In various embodiments, FEC encoder 232 may include compressor 504.Compressor 504 may be connected to reverse gearbox 502. Compressor 504receives the 66-bit block outputs from reverse gearbox 502. Compressor504 retrieves the two synchronization bits from each block, compressesthe two synchronization bits to one transcode bit (e.g., T₀ to T₃₁), andoutputs a 65-bit block comprising 64-bits of PCS payload and 1 transcodebit. Compressor 504 outputs the 65-bit blocks to parity generator 508and multiplexer 512. Compressor 504 also outputs a control signal toselector 506.

In various embodiments, FEC encoder 232 may include parity generator508. Parity generator 508 receives the 65-bit blocks from compressor504, and produces parity check bits for the blocks. For example, paritygenerator 508 uses the polynomial g(x) to generate the parity check bitsp(x), as described in more detail below. Parity generator 508 outputsthe parity check bits to multiplexer 514.

In various embodiments, FEC encoder 232 may include selector 506 andmultiplexer 512. Multiplexer 512 may receive the 65-bit blocks andparity check bits from compressor 504 and parity generator 508,respectively. Multiplexer 512 may also receive a selection signal fromselector 506. Multiplexer 512 may append the 32 parity check bits forthe 32 65-bit blocks (e.g., 32×65 bits=2080 bits) to the end of an FECframe (e.g., FEC frame 300) thereby making an FEC frame having 2112 bits(e.g., 2080 bits+32 parity check bits=2112 bits). Multiplexer 512 mayoutput the FEC frame to scrambler 514.

In various embodiments, FEC encoder 232 may include pseudo-noisegenerator 510. Pseudo-noise generator 510 may generate a pseudo-noisesequence, and output the pseudo-noise sequence to scrambler 514.

In various embodiments, scrambler 514 receives the FEC frame with the 32parity check bits and the pseudo-noise sequence from multiplexer 512 andpseudo-noise generator 510, respectively. Scrambler 514 may scramble theFEC frame using the pseudo-noise sequence. Scrambler 514 may output thescrambled FEC frame to a PMA service interface for PMA sublayer 240 viatx_data-group<15:0>.

In operation, FEC encoder 232 encodes the 32×65 bit payload blocks usinga (2112, 2080) code. The code is a shortened cyclic code that can beencoded by generator polynomial g(x). The cyclic code is well suited forcorrecting burst errors and therefore may also be referred to as abinary burst error correction code. The resulting payload blockincluding the T bits is scrambled using the PN-2112 pseudo-noisesequence of pseudo-noise generator 510. For example, compressor 504provides m(x) which is stream of 65b message bits to both paritygenerator 508 and multiplexer 512. Parity generator uses the g(x)polynomial to generate parity check bits p(x) for 32 65-bit blocks.Compressor 504 also sends a select signal for the first 32 65-bit blocksso that multiplexer 512 outputs m(x). Then it selects p(x) so thatmultiplexer 512 outputs p(x) at the end of every FEC block.

The generator polynomial g(x) for the (2112, 2080) parity check bits isdefined in accordance with Equation (1) as follows:

g(x)=x ³² +x ²³ +x ²¹ +x ¹¹ +x ²+1  Equation (1)

If the polynomial representation of information bits is denoted as m(x),the codeword denoted as c(x) can be calculated in systematic form asdefined in accordance with Equations (2) and (3) as follows:

p(x)=x ³² m(x)mod g(x)  Equation (2)

c(x)=p(x)+x ³² m(x)  Equation (3)

where multiplication on x³² is performed using shifts. Systematic formof the codeword means that first 2080 bits of the codeword c(x) areinformation bits that can be extracted directly.

FIG. 6 illustrates one embodiment of a pseudo-noise generator. FIG. 6illustrates a block diagram for pseudo-noise generator 510. In oneembodiment, for example, pseudo-noise generator 510 may comprise apseudo-noise sequence of length 2112 (PN-2112) generated by thepolynomial r(x), which is equal to the scrambler polynomial defined inthe Backplane Ethernet Specification having an initial state S₅₇=1,S_(i-1)=S_(i) XOR 1 or rather the binary sequence of “101010 . . . .”Before each FEC block processing (encoding or decoding), pseudo-noisegenerator 510 is initialized with the state of “101010 . . . .”Pseudo-noise generator 510 shall produce the same result as theimplementation shown in FIG. 6. This implements the PN-2112 generatorpolynomial as defined in accordance with Equation (4) as follows:

r(x)=1+x ³⁹ +X ⁵⁸  Equation (4)

Scrambling with the PN-2112 sequence at the FEC codeword boundary may benecessary for establishing FEC block synchronization to ensure that anyshifted input bit sequence is not equal to another FEC codeword, as wellas to ensure DC balance.

FIG. 7 illustrates one embodiment of a forward error correcting decoder.FIG. 7 illustrates an FEC decoder, such as FDBS 234. FDBS 234 performsFEC synchronization and decoding operations to reverse the FEC encodingoperations performed by FEC encoder 232. As shown in FIG. 7, FDBS 234may comprise a descrambler 702, a pseudo-noise generator 704, asynchronizer 706, a decoder 708, an error monitor 710, and areconstructor 712. Although FIG. 7 illustrates FDBS 234 with a limitednumber of elements by way of example, it may be appreciated that more orless elements may be used for FDBS 234 as desired for a givenimplementation. The embodiments are not limited in this context.

FDBS 234 initially performs FEC synchronization operations prior todecoding and error correcting operations. When the receive channel is innormal mode of operation, FDBS 234 continuously monitorsPMA_SIGNAL.indication (SIGNAL_OK). When SIGNAL_OK indicates OK, FDBS 234accepts data-units via the PMA_UNITDATA.indication primitive. FDBS 234attains block synchronization based on the decoding of FEC blocks andconveys received 64b/66b blocks to the PCS receive process of PCSsublayer 210. FDBS 234 sets the sync_status flag for PCS sublayer 210 toindicate whether FDBS 234 has obtained synchronization.

In various embodiments, FDBS 234 may include a descrambler 702.Descrambler 702 may receive data from PMA sublayer 240 viarx_data-group<15:0>. Descrambler 702 may also receive a PN-2112 sequencefrom pseudo-noise generator 704. The PN-2112 sequence may be similar tothe PN-2112 sequence generated by pseudo-noise generator 510.Descrambler 702 may use the PN-2112 sequence to descramble the datareceived from PMA sublayer 240. Descrambler 702 may output thedescrambled data to synchronizer 706.

In various embodiments, FDBS 234 may include synchronizer 706.Synchronizer 706 may perform FEC block synchronization based on repeateddecoding of the received sequence. To establish FEC synchronization,FDBS 234 recovers and extracts the information bits using the paritycheck bit data. For example, FDBS 234 may decode some FEC blocks. FDBS234 may take a random 2112 bit stream of data and calculate a parityusing the g(x) polynomial. FDBS 234 compares the calculated parity withthe 32-bit parity received at the end of a FEC block. If there is matchthen FDBS 234 has located the FEC block boundary. If there is no match,then FDBS 234 shifts the received bit stream by 1 bit, and performsparity comparison operations again. The shift and compare operations arerepeated until the received parity matches the computed parity. A matchindicates that the FEC block boundary is found or that synchronizationhas been achieved. Such operations are sometimes referred to as FECblock or frame delineation.

Once synchronization is achieved, then FDBS 234 may begin to recover the65-bit data from each of the FEC frames as received via the 16-bitrx_data-group<15:0> stream received from PMA sublayer 240. Aftersynchronization is achieved, the parity check may not match for some ofthe frames which may indicate an error.

In various embodiments, FDBS 234 may include decoder 708. Decoder 706may perform FEC decoding operations. Decoder 706 may decode the datareceived from PMA sublayer 240 into 65-bit blocks. The 65-bit blocks maycomprise, for example, the 64-bit payload information and 1 transcodingbit. Decoder 706 may output the 65-bit blocks to reconstructor 712.Decoder 706 may also output the decoded data and corresponding paritycheck bits to error monitor 710.

In various embodiments, FDBS 234 may include error monitor 710. Errormonitor 710 may monitor the decoded data for errors using FEC detectingtechniques. Error monitor 710 may use various counters to maintaincounts for a number of corrected blocks and a number of uncorrectedblocks. This statistical information can be used by a management entityregarding the quality of the physical medium, which in this case is abackplane channel. FDBS 234 may be arranged to indicate any decodingerrors to upper layers based on a configuration option. Theconfiguration options may be set in accordance with various operationmode flags received by FDBS 234. When FDBS 234 is arranged to indicatedecoding errors, FDBS 234 indicates such errors to PCS sublayer 210 bysetting both synchronization bits in each of the 64B/66B blocks to thesame value (e.g., “11”), thus forcing PCS sublayer 210 to consider theblock as invalid.

In various embodiments, FDBS 234 may include reconstructor 712. In caseof successful decoding, reconstructor 712 restores the synchronizationbits in each of the 64b/66b blocks. Reconstructor 712 may receive the65-bit blocks from decoder 708. Reconstructor 712 may reconstruct thesynchronization header for the 64-bit payload information using the 1transcoding bit. Reconstructor 712 may append the 2-bit synchronizationheader to the 64-bit payload information to reconstruct the original64b/66b block. Reconstructor 712 may send the reconstructed 64b/66bblocks to PCS sublayer 210 via rx_data-group<15:0>. Reconstructor 712and its reconstructed output may be described in more detail withreference to FIG. 8.

FIG. 8 illustrates one embodiment of a decoded data frame. FIG. 8illustrates a decoded data frame 800. Decoded data frame 800 maycomprise a reconstructed 64b/66b block suitable for use by PCS sublayer210. As shown in FIG. 8, decoded data frame 800 comprises 66 bits, withbits x0 and x1 comprising the 2 synchronization bits of synchronizationheader 802. Decoded data frame 800 may also illustrate the 65-bit outputof decoder 708 as bits x1 to x65. Reconstructor 712 may reconstruct thefirst synchronization bit x0 from the transcoded bit x1, add the firstsynchronization bit x0 to synchronization header 802, thereby forming areconstructed 64b/66b block comprising bits x0 to x65. FDBS 234 may sendthe reconstructed 64b/66b block to PCS sublayer 210.

Operations for the above embodiments may be further described withreference to the following figures and accompanying examples. Some ofthe figures may include a logic flow. Although such figures presentedherein may include a particular logic flow, it can be appreciated thatthe logic flow merely provides an example of how the generalfunctionality as described herein can be implemented. Further, the givenlogic flow does not necessarily have to be executed in the orderpresented unless otherwise indicated. In addition, the given logic flowmay be implemented by a hardware element, a software element executed bya processor, or any combination thereof. The embodiments are not limitedin this context.

FIG. 9 illustrates one embodiment of a first logic flow. FIG. 9illustrates a logic flow 900. Logic flow 900 may be representative ofthe operations executed by one or more embodiments described herein,such as reconstructor 712 of FDSB 234. More particularly, logic flow 900may illustrate reconstruction operations for FDSB 234. As shown in logicflow 900, each of the 32 65-bit data words is extracted from therecovered FEC block and the 2-bit synchronization header isreconstructed for the 64b/66b codes from the transcode bit at block 902.FDSB 234 provides a configuration option that indicates decoding errorsin the reconstructed synchronization bits. For example, theconfiguration option may instruct FDSB 234 to reconstructsynchronization bits to be one of the possible combinations “01” or “10”if decoding successful. Alternatively, the configuration option mayinstruct FDSB 234 to reconstruct synchronization bits to additionalcodes “00” and “11” if a decoding error has occurred. This informationcorresponds to one complete (2112, 2080) FEC frame that is equal to 3264b/66b code blocks.

In accordance with the configuration option, a determination may be madeas to whether decoding was successful (e.g., without errors) at block904. If decoding was successful, then a determination may be made as toa value for bit x1 of the 65-bit data block from decoder 708. If thevalue for bit x1 is equal to 0 (e.g., x1=0), then x0 is set to 1 (e.g.,x0=1), otherwise x0 is set to 0 (e.g., x0=0). In this case, thesynchronization header may comprise “01” or “10” to indicate validdecoding. If decoding was unsuccessful (e.g., with errors) at block 904,then a determination may be made as to a value for bit x1 of the 65-bitdata block from decoder 708. If the value for bit x1 is equal to 0(e.g., x1=0), then x0 is set to 0 (e.g., x0=0), otherwise x0 is set to 1(e.g., x0=1). In this case, the synchronization header may comprise “00”or “11” to indicate invalid decoding.

FIG. 10 illustrates one embodiment of a second logic flow. FIG. 10illustrates a logic flow 1000. Logic flow 1000 may be representative ofthe operations executed by one or more embodiments described herein,such as synchronizer 706 of FDSB 234. More particularly, logic flow 100may illustrates FEC synchronization operations for the 2112 bit FECframe using FEC decoding. Receive Frame synchronization may be achievedusing various n/m serial locking techniques as illustrated by logic flow1000. As shown in logic flow 1000, a candidate block start position fromthe FEC block synchronization buffer may be tested at block 1002. Paritymatching for the potential 2112 bit block may be performed at block 1006and evaluated at block 1008. If it fails, the candidate start bit may beshifted by one bit position at block 1004, and the operations for blocks1002, 1006 and 1008 may be repeated until decoding is successful atblock 1008.

If decoding is successful at block 1008, the potential block startposition may be validated by determining whether decoding operationswere successful (e.g., good parity) for n consecutive blocks at block1010. If any of them fail, the start position may be shifted one bitposition and the operations for blocks 1006, 1008 and 1010 may berepeated until good parity has been achieved for n consecutive blocks atblock 1010.

If decoding operations were successful for n consecutive blocks at block1010, synchronizer 706 may report FEC block synchronization has beenestablished at block 1012. Meanwhile, FEC block synchronization may bevalidated by continuously performing parity matching at block 1014 todetermine whether decoding operations were unsuccessful (e.g., badparity) at block 1016. If m consecutive blocks are received with badparity at block 1018, report a drop in FEC block synchronization atblock 1020, and restart FEC synchronization operations again at block1002. Otherwise, continue monitoring operations at blocks 1014, 1016 and1018 until m consecutive blocks are received with bad parity at block1018.

The FEC synchronization operations illustrated by logic flow 1000 may berepeated at most 2111 times for all bits positions in the 2112 codeword. For example, if a potential candidate start position is tested atblock 1008 and it does not match, then the buffer is shifted by 1 bitposition by block 1004 and then matched again at block 1006. This cycleof shifting and matching will be repeated at most 2111 times beforefinding a match or achieving synchronization. Assume the potential blockstart position is missed by 1 bit, the FEC synchronization operationsmay continue the shift and match operations for 2111 times (e.g.,2112-1=2111 bits) before a match is found. In one embodiment, forexample, the default values for m and n may be set to m=8 and n=4. Theembodiments are not limited in this context.

In various embodiments, FEC sublayer 230 shall have the capability toenable or disable FEC operations. For example, a management datainput/output (MDIO) interface or equivalent management interface shallbe provided to access the variable Enable_FEC as defined by theBackplane Ethernet Specification. When the Enable_FEC variable bit isset to a one, this enables FEC sublayer 230 operations for the 10GBASE-KR PHY. When the Enable_FEC variable bit is set to zero, FECsublayer 230 operations are disabled in the 10 GBASE-KR PHY. TheEnable_FEC variable shall be set to zero upon execution of PHY reset.When FEC operations are disabled, PHY unit 110 should include a bypasstechnique to bypass FEC encode/decode operations so as to not causeadditional latency associated with such encoding or decoding functions.

In various embodiments, auto-negotiation operations may also be used toenable FEC. Auto-negotiation may be used to negotiate the FEC capabilityby the link partners at both the ends, and then enable FEC only if bothends support FEC sublayer 230. The FEC capability can be negotiatedbetween peer devices using the auto-negotiation function as defined inclause 73 of the Backplane Ethernet Specification. For example, FEC (F0)is encoded in bit D47 of the base link code word. The default value islogic zero. When the FEC capability bit F0 is set to logic one, itindicates that the FEC function is enabled for 10 GBASE-KR PHY. Sincethe local device and the link partner may have enabled the FEC bitsdifferently, the priority resolution function is used to select the FECmodes in the device. The FEC is enabled on the link only if both endsadvertise the same status on the F0 bits. The embodiments are notlimited in this context.

In various embodiments, management and error monitoring operations forFEC sublayer 230 may be performed using various counters. The countersmay be accessed via an MDIO interface or equivalent managementinterface. The counters are reset to zero upon a read operation or uponreset of FEC sublayer 230. When a counter reaches all ones, it stopscounting. The purpose of the various counters is to assist in monitoringthe quality of the communication link.

In one embodiment, for example, FEC sublayer 230 may use aFEC_corrected_blocks_counter. The FEC_corrected_blocks_counter may countonce for each corrected FEC blocks processed. This is a 32-bit counter.This variable is provided by a management interface that may be mappedto the appropriate register as defined by the Backplane EthernetSpecification.

In one embodiment, for example, FEC sublayer 230 may use aFEC_uncorrected_blocks_counter. The FEC_uncorrected_blocks_counter maycount once for each uncorrected FEC blocks processed. This is a 32-bitcounter. This variable is provided by a management interface that may bemapped to the appropriate register as defined by the Backplane EthernetSpecification.

FIG. 11 illustrates one embodiment of a third logic flow. FIG. 11illustrates a logic flow 1100. Logic flow 1100 may be representative ofthe operations performed by FEC sublayer 230. In one embodiment, forexample, FEC may be performed using a single bit such as a transcode bitto represent a two bit synchronization header at block 1102. Theembodiments are not limited in this context.

In one embodiment, for example, a PCS block of information may beencoded by replacing the two bit synchronization header with the singletranscode bit. Encoding operations may include receiving physical codingsublayer blocks of information, replacing two synchronization bits fromeach block with a single transcode bit, generating parity check bits forthe blocks, and generating a forward error correction frame using theblocks and the parity check bits. The embodiments are not limited inthis context.

In one embodiment, for example, PMA block of information may be decodedby reconstructing the two bit synchronization header using the singletranscode bit. Decoding operations may include receiving physical codingsublayer blocks of information, decoding each physical coding sublayerblock, retrieving a parity check bit for each physical coding sublayer,and performing forward error correction using the parity check bits. Theembodiments are not limited in this context.

FIG. 12 illustrates one embodiment of a communications system. FIG. 12illustrates a communications system 1200 suitable for use with networkinterface 100. In one embodiment, for example, communications system1200 may comprise a communication system having multiple nodes. A nodemay comprise any physical or logical entity for communicatinginformation in communications system 1200 and may be implemented ashardware, software, or any combination thereof, as desired for a givenset of design parameters or performance constraints. Although FIG. 12 isshown with a limited number of nodes in a certain topology, it may beappreciated that system 1200 may include more or less nodes in any typeof topology as desired for a given implementation. The embodiments arenot limited in this context.

In various embodiments, a node may comprise a processing system, acomputer system, a computer sub-system, a computer, a workstation, aterminal, a server, a bladed server, a modular server, a line card, aswitching subsystem, a bridge, a router or a combination thereof, apersonal computer (PC), a laptop computer, an ultra-laptop computer, aportable computer, a handheld computer, a personal digital assistant(PDA), a microprocessor, an integrated circuit, a programmable logicdevice (PLD), a digital signal processor (DSP), a processor, a circuit,a logic gate, a register, a microprocessor, an integrated circuit, asemiconductor device, a chip, a transistor, and so forth. Theembodiments are not limited in this context.

In various embodiments, a node may comprise, or be implemented as,software, a software module, an application, a program, a subroutine, aninstruction set, computing code, words, values, symbols or combinationthereof. A node may be implemented according to a predefined computerlanguage, manner or syntax, for instructing a processor to perform acertain function. Examples of a computer language may include C, C++,Java, BASIC, Perl, Matlab, Pascal, Visual BASIC, assembly language,machine code, micro-code for a processor, and so forth. The embodimentsare not limited in this context.

Communications system 1200 may be implemented as a wired communicationsystem, a wireless communication system, or a combination of both.Although communications system 1200 may be illustrated using aparticular communications media by way of example, it may be appreciatedthat the principles and techniques discussed herein may be implementedusing any type of communication media and accompanying technology. Theembodiments are not limited in this context.

When implemented as a wired system, for example, communications system1200 may include one or more nodes arranged to communicate informationover one or more wired communications media. Examples of wiredcommunications media may include a wire, cable, printed circuit board(PCB), backplane, midplane, switch fabric, semiconductor material,twisted-pair wire, co-axial cable, fiber optics, and so forth. Thecommunications media may be connected to a node using an input/output(I/O) adapter. The I/O adapter may be arranged to operate with anysuitable technique for controlling information signals between nodesusing a desired set of communications protocols, services or operatingprocedures. The I/O adapter may also include the appropriate physicalconnectors to connect the I/O adapter with a correspondingcommunications medium. Examples of an I/O adapter may include a networkinterface, a NIC, disc controller, video controller, audio controller,and so forth. The embodiments are not limited in this context.

When implemented as a wireless system, for example, communicationssystem 1200 may include one or more wireless nodes arranged tocommunicate information over one or more types of wireless communicationmedia, sometimes referred to herein as wireless shared media. An exampleof a wireless communication media may include portions of a wirelessspectrum, such as the radio-frequency (RF) spectrum. The wireless nodesmay include components and interfaces suitable for communicatinginformation signals over the designated wireless spectrum, such as oneor more antennas, wireless transceivers, amplifiers, filters, controllogic, and so forth. As used herein, the term “transceiver” may be usedin a very general sense to include a transmitter, a receiver, or acombination of both. Examples for the antenna may include an internalantenna, an omni-directional antenna, a monopole antenna, a dipoleantenna, an end fed antenna, a circularly polarized antenna, amicro-strip antenna, a diversity antenna, a dual antenna, an antennaarray, a helical antenna, and so forth. The embodiments are not limitedin this context.

As shown in FIG. 12, communications system 1200 may include multiplenetwork devices 1205 coupled to physical medium 120 using networkinterface 100. In various embodiments, network interface 100 and/ornetwork devices 1205 may include a processor. The processor may beimplemented using any processor or logic device, such as a complexinstruction set computer (CISC) microprocessor, a reduced instructionset computing (RISC) microprocessor, a very long instruction word (VLIW)microprocessor, a processor implementing a combination of instructionsets, or other processor device. In one embodiment, for example, theprocessor may be implemented as a general purpose processor, such as aprocessor made by Intel® Corporation, Santa Clara, Calif. The processormay also be implemented as a dedicated processor, such as a controller,microcontroller, embedded processor, a digital signal processor (DSP), anetwork processor, a media processor, an input/output (I/O) processor, amedia access control (MAC) processor, a radio baseband processor, afield programmable gate array (FPGA), a programmable logic device (PLD),and so forth. The embodiments, however, are not limited in this context.

In one embodiment, network interface 100 and/or network devices 1205 mayinclude a memory to connect to the processor. The memory may beimplemented using any machine-readable or computer-readable mediacapable of storing data, including both volatile and non-volatilememory. For example, the memory may include read-only memory (ROM),random-access memory (RAM), dynamic RAM (DRAM), Double-Data-Rate DRAM(DDRAM), synchronous DRAM (SDRAM), static RAM (SRAM), programmable ROM(PROM), erasable programmable ROM (EPROM), electrically erasableprogrammable ROM (EEPROM), flash memory, polymer memory such asferroelectric polymer memory, ovonic memory, phase change orferroelectric memory, silicon-oxide-nitride-oxide-silicon (SONOS)memory, magnetic or optical cards, or any other type of media suitablefor storing information. It is worthy to note that some portion or allof the memory may be included on the same integrated circuit as theprocessor, or alternatively some portion or all of the memory may bedisposed on an integrated circuit or other medium, for example a harddisk drive, that is external to the integrated circuit of the processor.The embodiments are not limited in this context.

As previously described, FEC sublayer 230 may use a binary burst errorcorrection code of rate (2112, 2080) encode transmissions over highspeed serial networks. The Backplane Ethernet Specification specifiesthe use of a decision feedback equalizer (DFE) as a tool for intersymbolinterference (ISI) cancellation. The DFE output bitstream, however,typical has grouping errors also referred as error bursts due to errorpropagation in the DFE. Consequently, FEC sublayer 230 uses the (2112,2080) code. The (2112, 2080) code is a shortened cyclic binary bursterror correction code with 32 redundant bits (also called parity checkbits). This is a highly efficient code that provides the capability fora receiver at the receiving end of the network to correct error burstsup to 11 or 16 bits in length with relatively low latency. The code isgenerated using the generator polynomial g(x) as previously specified inEquation (1).

FIGS. 13-19 illustrate various graphs. Each graph illustrates valuesrepresenting bit error rates (BER) on a y-axis, and values representingsignal-to-noise-ratio (SNR) in decibels (dB) on an x-axis. Each graphmay be used to compare a BER of the (2112, 2080) code and uncodedtransmission in various backplane channels. For example, each graphshows a coding gain using the binary burst error correction code of rate(2112, 2080), where for any particular BER the difference between theuncoded and coded plot lines provide the coding gain for that particularBER.

FIGS. 13-15 may illustrate various simulations related to backplanesmade by Intel Corporation. FIGS. 13-15 may illustrate graphs 1300, 1400and 1500, respectively. Graphs 1300-1500 may be used to compare a BER ofthe (2112, 2080) code and uncoded transmission for various backplanechannels T12, M20 and B1. SNR is equal to the SNR at a slicer withsimulations to BER of 10⁻⁸/10⁻⁹ and extrapolated to 10⁻¹². Graphs1300-1500 indicate that simulations show an approximate 2 dB coding gainat a BER of 10⁻⁹, for example.

FIGS. 16-17 may illustrate various simulations related to backplanesmade by Tyco International, Ltd. FIGS. 16-17 may illustrate graphs 1600and 1700, respectively. Graphs 1600, 1700 may be used to compare a BERof the (2112, 2080) code and uncoded transmission for various backplanetest channels of Case 3 and Case 4. SNR is equal to the SNR at a slicerwith simulations to BER of 10⁻⁸/10⁻⁹ and extrapolated to 10⁻¹². Graphs1600, 1700 indicate that simulations also show an approximate 2 dBcoding gain at a BER of 10⁻⁹, for example.

FIGS. 18-19 may illustrate various simulations related to backplanesmade by Molex®. FIGS. 18-19 may illustrate graphs 1800 and 1900,respectively. Graphs 1800, 1900 may be used to compare a BER of the(2112, 2080) code and uncoded transmission for various backplane testchannels of Inbound J4K4G4H4 and Outbound J3K3G3H3. SNR is equal to theSNR at a slicer with simulations to BER of 10⁻⁸/10⁻⁹ and extrapolated to10⁻¹². Graphs 1600, 1700 indicate that simulations also show anapproximate 2 dB coding gain at a BER of 10⁻⁹, for example.

As shown in graphs 1300-1900, the (2112, 2080) code enables serialcommunications over channels that may not operate with traditionalnon-return-to-zero (NRZ) or 8b/10b or 64/66b encoding by providing anadditional 2 dB or more of equivalent SNR gain over data that was notcoded using this technique. The code requires reduced overhead at thetransmitter and uses the same transmit rate as the 64/66b code. Theencoding and decoding algorithms have a relatively lower complexity andcan be implemented in silicon with less than approximately 50,000 gates.

The (2112, 2080) codes may have several advantages over previoustechniques. For example, the code may achieve approximately 2 dB or moreof SNR gain over NRZ with 8b/10b or 64/66b encoded signals. In anotherexample, the code can detect and correct error bursts up to 11 bits inlength induced by, for example, the communication channel. In yetanother example, the code may use the same transmit overhead as the64/66b code for 10 Gbps communications and uses the same encodeboundaries. In still another example, the code provides for lowerlatency at the receiver to decode and correct the errors, with a latencyof only 2112 bits or approximately 200 nanoseconds (ns) at 10 Gbps datarates. In yet another example, the code allows high speed serialcommunication (e.g., 10 Gbps or above) to operate over channels whichare mass manufactured using FR-4 and standard high volume manufacturingtechniques, and also provides additional margin to account forvariations in manufacturing and environmental conditions. In stillanother example, the code is readily adaptable to other standards orencoding schemes. The code can be adapted to work with 64/66b code toprovide another layer of error correction capability, and can also beused in any high speed serial network architecture, including Ethernetarchitectures, Infiniband architectures, FibreChannel architectures,PCI-Express architectures, and so forth. The embodiments are not limitedin this context.

Numerous specific details have been set forth herein to provide athorough understanding of the embodiments. It will be understood bythose skilled in the art, however, that the embodiments may be practicedwithout these specific details. In other instances, well-knownoperations, components and circuits have not been described in detail soas not to obscure the embodiments. It can be appreciated that thespecific structural and functional details disclosed herein may berepresentative and do not necessarily limit the scope of theembodiments.

It is also worthy to note that any reference to “one embodiment” or “anembodiment” means that a particular feature, structure, orcharacteristic described in connection with the embodiment is includedin at least one embodiment. The appearances of the phrase “in oneembodiment” in various places in the specification are not necessarilyall referring to the same embodiment.

Some embodiments may be implemented using an architecture that may varyin accordance with any number of factors, such as desired computationalrate, power levels, heat tolerances, processing cycle budget, input datarates, output data rates, memory resources, data bus speeds and otherperformance constraints. For example, an embodiment may be implementedusing software executed by a general-purpose or special-purposeprocessor. In another example, an embodiment may be implemented asdedicated hardware. In yet another example, an embodiment may beimplemented by any combination of programmed general-purpose computercomponents and custom hardware components. The embodiments are notlimited in this context.

Various embodiments may be implemented using one or more hardwareelements. In general, a hardware element may refer to any hardwarestructures arranged to perform certain operations. In one embodiment,for example, the hardware elements may include any analog or digitalelectrical or electronic elements fabricated on a substrate. Thefabrication may be performed using silicon-based integrated circuit (IC)techniques, such as complementary metal oxide semiconductor (CMOS),bipolar, and bipolar CMOS (BiCMOS) techniques, for example. Examples ofhardware elements may include processors, microprocessors, circuits,circuit elements (e.g., transistors, resistors, capacitors, inductors,and so forth), integrated circuits, application specific integratedcircuits (ASIC), programmable logic devices (PLD), digital signalprocessors (DSP), field programmable gate array (FPGA), logic gates,registers, semiconductor device, chips, microchips, chip sets, and soforth. The embodiments are not limited in this context.

Various embodiments may be implemented using one or more softwareelements. In general, a software element may refer to any softwarestructures arranged to perform certain operations. In one embodiment,for example, the software elements may include program instructionsand/or data adapted for execution by a hardware element, such as aprocessor. Program instructions may include an organized list ofcommands comprising words, values or symbols arranged in a predeterminedsyntax, that when executed, may cause a processor to perform acorresponding set of operations. The software may be written or codedusing a programming language. Examples of programming languages mayinclude C, C++, BASIC, Perl, Matlab, Pascal, Visual BASIC, JAVA,ActiveX, assembly language, machine code, and so forth. The software maybe stored using any type of computer-readable media or machine-readablemedia. Furthermore, the software may be stored on the media as sourcecode or object code. The software may also be stored on the media ascompressed and/or encrypted data. Examples of software may include anysoftware components, programs, applications, computer programs,application programs, system programs, machine programs, operatingsystem software, middleware, firmware, software modules, routines,subroutines, functions, methods, procedures, software interfaces,application program interfaces (API), instruction sets, computing code,computer code, code segments, computer code segments, words, values,symbols, or any combination thereof. The embodiments are not limited inthis context.

Some embodiments may be described using the expression “coupled” and“connected” along with their derivatives. It should be understood thatthese terms are not intended as synonyms for each other. For example,some embodiments may be described using the term “connected” to indicatethat two or more elements are in direct physical or electrical contactwith each other. In another example, some embodiments may be describedusing the term “coupled” to indicate that two or more elements are indirect physical or electrical contact. The term “coupled,” however, mayalso mean that two or more elements are not in direct contact with eachother, but yet still co-operate or interact with each other. Theembodiments are not limited in this context.

Some embodiments may be implemented, for example, using amachine-readable medium or article which may store an instruction or aset of instructions that, if executed by a machine, may cause themachine to perform a method and/or operations in accordance with theembodiments. Such a machine may include, for example, any suitableprocessing platform, computing platform, computing device, processingdevice, computing system, processing system, computer, processor, or thelike, and may be implemented using any suitable combination of hardwareand/or software. The machine-readable medium or article may include, forexample, any suitable type of memory unit, memory device, memoryarticle, memory medium, storage device, storage article, storage mediumand/or storage unit, for example, memory, removable or non-removablemedia, erasable or non-erasable media, writeable or re-writeable media,digital or analog media, hard disk, floppy disk, Compact Disk Read OnlyMemory (CD-ROM), Compact Disk Recordable (CD-R), Compact DiskRewriteable (CD-RW), optical disk, magnetic media, magneto-opticalmedia, removable memory cards or disks, various types of DigitalVersatile Disk (DVD), a tape, a cassette, or the like. The instructionsmay include any suitable type of code, such as source code, compiledcode, interpreted code, executable code, static code, dynamic code, andthe like. The instructions may be implemented using any suitablehigh-level, low-level, object-oriented, visual, compiled and/orinterpreted programming language, such as C, C++, Java, BASIC, Perl,Matlab, Pascal, Visual BASIC, assembly language, machine code, and soforth. The embodiments are not limited in this context.

Unless specifically stated otherwise, it may be appreciated that termssuch as “processing,” “computing,” “calculating,” “determining,” or thelike, refer to the action and/or processes of a computer or computingsystem, or similar electronic computing device, that manipulates and/ortransforms data represented as physical quantities (e.g., electronic)within the computing system's registers and/or memories into other datasimilarly represented as physical quantities within the computingsystem's memories, registers or other such information storage,transmission or display devices. The embodiments are not limited in thiscontext.

While certain features of the embodiments have been illustrated asdescribed herein, many modifications, substitutions, changes andequivalents will now occur to those skilled in the art. It is thereforeto be understood that the appended claims are intended to cover all suchmodifications and changes as fall within the true spirit of theembodiments.

1. An apparatus, comprising: circuitry of a forward error correction(FEC) sublayer to perform forward error correction, the FEC sublayercoupled to a physical coding sublayer and a physical medium attachment(PMA) sublayer the FEC sublayer comprising an encoder having: a reversegearbox; a compressor coupled to said reverse gearbox; a selectorcoupled to said compressor; a parity generator coupled to saidcompressor; a multiplexer coupled to said compressor, selector and saidparity generator; a scrambler coupled to said multiplexer; and apseudo-noise generator coupled to said scrambler.
 2. The apparatus ofclaim 1, wherein the FEC sublayer circuitry comprises a processor. 3.The apparatus of claim 1, wherein the FEC sublayer comprises a pluralityof hardware components forming a part of a hardware physical layer unit.4. The apparatus of claim 1, wherein the PCS block has 66 bits includingthe two bit synchronization header.
 5. The apparatus of claim 1,comprising a forward error correction decoder and block synchronizer tocomprise: a descrambler; a pseudo-noise generator to couple to saiddescrambler; a synchronizer to couple to said descrambler; a decoder tocouple to said synchronizer; an error monitor to couple to said decoder;and a reconstructor to couple to said decoder.